## How to do it

In Haskell, this is actually very easy:

```
Prelude Control.Monad> liftM2 (+) (* 2) (* 3) 10
50
```

Or, alternatively:

```
Prelude Control.Applicative> (+) <$> (* 2) <*> (* 3) $ 10
50
```

Or, more verbosely:

```
import Control.Monad
main :: IO ()
main = do let (+$) = liftM2 (+) -- Define a new infix operator
let double = (* 2)
let triple = (* 3)
print $ (double +$ triple) 10
```

What's happening here? Haskell's a very alien language if your experience lies in PHP and JavaScript, so I'll try to break it down. But just a heads up: the relevant functions here (`liftM2`

and `<$>`

/`<*>`

) are much more general than simply this usage, which can make understanding them difficult at first. The resulting power, however, is worth it.

## High-level summary

Here's my attempt at a very high level summary: `liftM2`

takes a binary function `op`

and produces a binary function which operates on "more complicated" values. If your "more complicated" values are one-argument functions `f`

and `g`

, there's only one good way to combine them and produce a new one-argument function: produce a function which passes its argument `x`

to `f`

and to `g`

, and then computes `f x `op` g x`

—it combines their results by using `op`

. In JavaScript, this would be something like

```
function liftM2_functions(op) {
return function (f,g) {
return function (x) { op(f(x), g(x)) }
}
}
```

Since `liftM2`

only works on binary functions, there's also `liftM3`

for ternary functions, and so on, but this is messy; thus, the `<$>`

and `<*>`

operators were introduced, such that `liftM`*n* f a1 a2 ... a*n*

is exactly equivalent to `f a1 <*> a2 <*> ... <*> a`*n*

.

## Details

If you want a much more detailed answer, read on. I will warn you that I'm not sure how clear this is; it relies on some concepts which I have to semi-handwave, and I may not have done a good job. But if you're game, here we go.

First, let's just explain some Haskell syntax:

`(* 2)`

and `(* 3)`

are short-hand ways of writing `\x -> x*2`

and `\x -> x*3`

, which are just Haskell for the JavaScript `function (x) { return x*2 }`

and `function (x) { return x*3 }`

.
`(+)`

is just the function which performs addition; it's the prefix form of the infix operator `+`

.
`f x`

is function application `f(x)`

; `f x y`

is parsed as `(f x) y`

, but can be considered two-argument function application `f(x,y)`

.
- The
`$`

infix operator is also function application, but with lower precedence: `... $ x`

is parsed as `(...) x`

.
`<$>`

and `<*>`

are fancy infix operators.

### Types

So! With that out of the way, let's consider the first snippet first. In `liftM2 (+) (* 2) (* 3) 10`

, the "function addition function" you want is `liftM2 (+)`

; its two arguments are `(* 2)`

and `(* 3)`

; and the argument to the result of *that* is `10`

. What's going on? In Haskell, the right way to think about this is in terms of types. Here are the relevant types—but be warned, you probably won't understand them immediately.

```
liftM2 :: Monad m => (a -> b -> r) -> m a -> m b -> m r
(+) :: Num a => a -> a -> a
(* 2) :: Num a => a -> a
(* 3) :: Num a => a -> a
10 :: Num a => a
```

Here, `f :: t`

means "`f`

has the type `t`

". These types are pretty abstract, so lets simplify some things. When you see `Num a`

, it means "for some type `a`

which is a number"; we can think about this as, for instance, `Int`

or `Double`

. So that gives us

```
(+) :: Int -> Int -> Int
(* 2) :: Int -> Int
(* 3) :: Int -> Int
10 :: Int
```

Alright, `10`

is an integer. And what about `(* 2)`

and `(* 3)`

? These are functions, denoted by the `->`

, which map an integer to an integer. You know that `(+)`

is a binary function on integers, so you might think it would have the type `(Int,Int) -> Int`

. However, in Haskell, the right way to think about this is as a function which takes an integer and *returns another function*; this is called currying. In JavaScript, this would be implemented as

```
function add(x) {
return function (y) {
return x + y
}
}
// Usage: add(10)(11) = 21.
```

You might not understand why this is good, but it will become relevant in a bit.

Now, let's tackle `liftM2 :: Monad m => (a -> b -> r) -> m a -> m b -> m r`

. What on *earth* is going on here? Ignoring the `Monad m`

bit, this says that `liftM2`

takes a two-argument function, a "monadic `a`

", and a "monadic `b`

", and produces a "monadic `r`

". However—thanks to currying—this is the same as saying that `liftM2`

takes a two-argument function and *returns* a two-argument function whose arguments and results are monadic: `liftM2 :: Monad m => (a -> b -> r) -> (m a -> m b -> m r)`

. So that's what's happening here: `liftM2 (+)`

is a monadic version of addition.

### Monads (don't panic!)

Now, I keep using the word monadic, and I haven't defined it. And I'm not going to! There are plenty of monad tutorials on the web, and some are even good; if you're curious, check out "You Could Have Invented Monads!". Here's all you need to understand for the moment: a monadic value is one which is "augmented" in some way, by having some extra structure around it. Since lists are a monad, `[1,2,3]`

is a monadic int in the list monad; there, the structure is that it's an int which could be either one or two or three. We are concerned with the *reader monad* here: a monadic int in this case is just a function which takes some object of type `a`

and returns an int. The idea is that it's an integer which can read and depend on some environment.

So, what we have here is exactly that. `(* 2)`

is a function which takes and returns an integer. Specializing the type of `liftM2`

to use the reader monad, we end up with the following:

```
liftM2 :: (a -> b -> r) -> ((e -> a) -> (e -> b) -> (e -> r))
```

Now this is promising! The `liftM2`

function is taking a binary function, and producing a function *which itself acts on functions*. Applying it to `(+) :: Int -> Int -> Int`

, we get

```
liftM2 (+) :: (e -> Int) -> (e -> Int) -> (e -> Int)
```

If you think about it, this is the type of addition of functions: `liftM2 (+)`

takes two one-argument functions, and produces a new one-argument function, and it does so by adding their results.

Now, how is `liftM2`

implemented? Like so (a reformatted version of the real implementation):

```
liftM2 f m1 m2 = do x1 <- m1
x2 <- m2
return $ f x1 x2
```

What's going on here? This says "get a value of type `a`

out of `m1`

, get another out of `m2`

, and combine those values with the given `f`

". Inside our reader monad (single-argument functions), `m1 :: e -> Int`

, and `x1 <- m1`

applies `m1`

to the "environment", which in our example is `10`

. So in our case, we have

```
do doubled <- (* 2)
tripled <- (* 3)
return $ doubled + tripled
```

This whole expression, of course, must depend on the mystery environment, since I've never mentioned it anywhere. So *its* type is `Int -> Int`

: a function which takes an int, doubles and triples it, and ads the two together. Which is, of course, where we started.

### Applicative functors (keep not panicking!)

What about `<$>`

and `<*>`

? I explained them at a very high level above, and I can tell you the basic idea: `<$>`

is like a `liftM1`

function, and `<*>`

applies "complicated" functions to "complicated" values. Their actual types are

```
(<$>) :: Functor f => (a -> b) -> f a -> f b
(<*>) :: Applicative f => f (a -> b) -> f a -> f b
```

I'm not going to explain these in detail here, because I don't think I can do a very good job. In one sentence, an object in a functor is in some sense a plain value with extra complications, and `<$>`

(also called `fmap`

) leaves the complications alone and applies a function to the plain old value inside. And `<*>`

is part of the extra structure which allows you to apply functions to multiple plain values inside multiple structures at once. But if you want more information, it's out there (although I don't know a good resource—people often recommend *Learn You A Haskell*, though).

## Conclusion

By leveraging some powerful constructs (applicative functors and/or monads), we can get this notion of function addition basically for free, and lots more besides. (Function multiplication? `liftM2 (*)`

. Function-level if-then-else? `liftM3 if' where if' c t f = if c then t else f`

. And so on.) And the great thing about Haskell is that *these advanced features are baked in*. Functors and monads are defined in the Prelude, the module which is implicitly included in every Haskell program (like Java's `java.lang`

namespace); the `Control.Monad`

module (which defines `liftM2`

) and the `Control.Applicative`

module (which defines applicative functors, `<$>`

, and `<*>`

) are part of the standard library^{1}. Haskell's higher-order and statically-typed nature allows it to leverage these concepts; doing this in PHP or Java would be basically impossible, and while JavaScript could express some of the concepts, the fact that it's dynamically typed means that the implementation would have to look very different. Other languages such as Scala can and do leverage these concepts as well, although Scala's the only one I can think of off the top of my head (and they are provided in Scalaz, not the standard library). The take-home message is that having access to these high-powered abstractions allows you to write simpler code, and less of it, to do the less-abstract things—such as function addition—that you want to do.

**1:** To be fair, `Control.Applicative`

is not in the Haskell 2010 standard. However, it is included by default with GHC, by far the most used Haskell compiler (it's the de-facto standard), as well as Hugs (a Haskell interpreter which had significant usage but has been losing ground to GHC), and as far as I can tell, JHC and YHC (two other compilers) as well. And there's nothing stopping an unrelated Haskell compiler from building Control.Applicative, as the code is completely conformant to Haskell 2010.

`Also, is there a place I can learn calculus from a source that isn't 10000 years old?`

Why, has it changed over the past 10,000 years? – animuson♦ Sep 4 '11 at 1:24